The Role of FAIR Data towards Sustainable Agricultural Performance: A Systematic Literature Review

Feeding a growing global population requires improving agricultural production in the face of multidimensional challenges; and digital agriculture is increasingly seen as a strategy for better decision making. Agriculture and agricultural supply chains are increasingly reliant on data, including its access and provision from the farm to the consumer. Far-reaching data provision inevitably needs the adoption of FAIR (Findable, Accessible, Interoperable, and Reusable) that offer data originators and depository custodians with a set of guidelines to safeguard a progressive data availability and reusability. Through a systematic literature review it is apparent that although FAIR data principles can play a key role in achieving sustainable agricultural operational and business performance, there are few published studies on how they have been adopted and used. The investigation examines: (1) how FAIR data assimilate with the sustainability framework; and (2) whether the use of FAIR data by the agriculture industry, has an impact on agricultural performance. The work identifies a social science research gap and suggests a method to guide agriculture practitioners in identifying the specific barriers in making their data FAIR. By troubleshooting the barriers, the value propositions of adopting FAIR data in agriculture can be better understood and addressed.


Introduction
The global need for agricultural production has been increasing [1], and most food production remains soil-based. With nearly all arable land under cultivation [2], agriculture is projected to encounter several challenges including: sustaining maximum production, limited natural resources, endangered environments and ecosystems, soil degradation and erosion [3,4]. It is quantitatively confirmed that farming strategies, methods and decision making are key factors in the future of sustainable and enhanced agricultural production [5,6]. Operationally, digital agriculture and data/information mutually rely on each other [3,7,8]. The volume of digital data in agricultural landscapes has grown exponentially, much of it collected by sensors (both remote sensing and the Internet of Things). Agricultural knowledge building, appropriate management responses [9] and farm management decisions [10] highly depend on the data collected through the use of digital technologies, and ubiquitous internet technologies provide access to all these data, delivered on demand via high-speed broadband to mobile tablet devices [11]. Precision agriculture technology employs data [12] to perform operations such as economising crop inputs, optimising machinery performance and appropriate location finding [13]. The digital agricultural revolution has led to a plethora of websites and mobile applications (Apps) that are now available to assist the farmer, agronomist, agribusiness investor, landscape manager and researcher in decision making. However, the applications and tools are only as good as the data they use, and because of the disparity of data collection, formats, and storage only a fraction of the required data are utilised. Current common is in its infancy in agricultural systems despite recognition of its value and development of guidelines.
This study conducts a systematic literature review aimed at: (1) understanding the adoption and use of FAIR data principles in the agriculture industry; (2) demonstrating by what means the sub-indicator/characteristics of FAIR data complement sustainable agricultural performance indicators, and the way the sustainability indicators assimilates with the sustainable agricultural performance indicators; and (3) whether FAIR data have impacted agricultural industry performance. Furthermore, this study uniquely describes how the adoption of FAIR data contribute to sustainable agricultural (operational and business) performance, by summarising the literature with comprehensive methodological approaches that demonstrate FAIR data implementation processes. The research identifies a social science research gap and suggests a method to guide agriculture practitioners in identifying the specific barriers to making their data FAIR, and to duly analyse the barriers to better understand and address the value propositions of adopting FAIR data in agriculture.

Methodology
This systematic literature review follows more rigorous and transparent methodology, following guidelines by Van der Knaap et al. [29], Moher et al. [30] and Koutsos et al. [31].

Scoping
This study attempts to answer two related research questions: To what extent have FAIR data principles been adopted by the agricultural industry? and what role do FAIR data principles play in agricultural performance?
The research uses the Web of Science digital database, initially created by the Institute for Scientific Information (ISI) but now maintained by Clarivate [32], to search for more authentic and comprehensive scientific literature. Considering the multidisciplinary nature of FAIR data in agriculture, the search includes all the relevant Web of Science categories and pertinent publications/journals. The broad literature search shows a clearer research gap in this area, with no previous studies found that address the above research questions.

Planning
To find the qualified publications from the Web of Science, a far-reaching search approach was carried out by using the most appropriate terms or keywords (given below), combining with the Boolean operators (AND and OR). The search query we used is as follows: ("FAIR data" OR "FAIR data principles" OR "FAIR data guidelines" OR " FAIR principles" OR "FAIR guidelines" OR "findability" OR "accessibility" OR "interoperability" OR "reusability" OR "findable" OR "accessible" OR "interoperable" OR "reusable" OR "datasets" OR "data sources") AND ("metadata standards" OR "metadata schema" OR "metadata schenes" OR "big date" OR "data management" OR "database") The search was limited by document type (article, review), years (2016-present) and language (English). Following eligibility criteria, an additional search was conducted through Google Scholar [33], applying the 'snowballing' (or 'backward and forward snowball') technique [34]. The search was broadened because: (1) FAIR data are a relatively new subject in the agriculture disciplines; and (2) agriculture is a multidimensional and multidisciplinary subject that encompasses sociology, data science, economic, environmental sciences, etc. The suitability criterium of the additional literature was assessed as being peer-reviewed (approved by two independent reviewers), following Van derWindt et al. [35] guidelines.
The selection criteria of the selected studies through the Web of Science were based on: (1) the role of FAIR data towards agricultural performance; (2) the implementation of FAIR data principles: i.e., applied research; (3) a comprehensive methodological approach, tools At the initial stage, the total number of studies obtained was 1042. To further confine the research focus to agriculture, the selection excluded numerous journals having entirely different scope areas, for instance medical sciences, astronomy, industrial engineering, computation and mathematics, etc. bringing the total number of studies to be assessed to 469. There were five studies included through the 'Google Scholar' search. More details are provided in the PRISMA (Preferred Reporting Items for Systematic reviews and Meta-Analyses) statement ( Figure 1). The selection criteria of the selected studies through the Web of Science were based on: (1) the role of FAIR data towards agricultural performance; (2) the implementation of FAIR data principles: i.e., applied research; (3) a comprehensive methodological approach, tools and/or rules, etc. To exclude studies not related to agricultural research (exclusion criteria), the query results were refined by choosing most appropriate Web of Science categories: (1) Agriculture Multidisciplinary; (2) Agriculture Dairy Animal Science; (3) Soil Science; (4) Plant Sciences; (5) Green Sustainable Science Technology; and (6) Computer Science Interdisciplinary Applications.
This review includes all the studies (with document type article, review) from the last six years (2016-present) since the FAIR data principles were first published in 2016. The search was confined to English language papers published by the top five publishing houses, i.e., Elsevier, Springer Nature, MDPI, Wiley and Taylor & Francis, since that covered most high-quality peer-reviewed papers.
At the initial stage, the total number of studies obtained was 1042. To further confine the research focus to agriculture, the selection excluded numerous journals having entirely different scope areas, for instance medical sciences, astronomy, industrial engineering, computation and mathematics, etc. bringing the total number of studies to be assessed to 469. There were five studies included through the 'Google Scholar' search. More details are provided in the PRISMA (Preferred Reporting Items for Systematic reviews and Meta-Analyses) statement ( Figure 1).

Identification/Search
Details of the studies found through the 'advanced search option' of the Web of Science were exported into a reference manager (Endnote) and spreadsheet (Excel) for further assessments. A Google Scholar search was again used to ensure that the maximum number of relevant papers were captured, given the multidisciplinary and multidimensional nature of the research objective. The snowballing technique was helpful for additional searching as there was a limit on searching imposed in the Web of Science database.

Identification/Search
Details of the studies found through the 'advanced search option' of the Web of Science were exported into a reference manager (Endnote) and spreadsheet (Excel) for further assessments. A Google Scholar search was again used to ensure that the maximum number of relevant papers were captured, given the multidisciplinary and multidimensional nature of the research objective. The snowballing technique was helpful for additional searching as there was a limit on searching imposed in the Web of Science database. All studies obtained from the search queries were fully checked based on their titles, abstracts, keywords, year of publication and the research area and so on, to confirm their eligibility for inclusion.

Screening
All the eligible literature found though the Web of Science and Google Scholar searches were saved (with title, keywords, abstracts) in two separate files. Duplicates (3 studies) were deleted. That resulted in 42 studies (full text) downloaded for a thorough assessment.

Eligibility/Assessment
The inclusion criteria comprise studies that: (1) cover the role of FAIR data in relation to agricultural performance; (2) take a FAIR data approach to agricultural data; and (3) include a comprehensive methodological segment on the practical implementation of FAIR data principles. As shown in Figure 1, out of 469 studies, 45 records remained after being refined. After deletion of duplicate studies, abstract reading and full-text skimming, there were 12 studies to be considered for full-text assessment.
Since the primary process of this systematic review has been to find studies that clearly describe the role of FAIR data in relation to agricultural performance, as well as evidence (i.e., a methodology approach) of the practical implementation of FAIR data principles, the selected papers were assigned a strength of evidence based on a grading system, described in Table 1: Table 1. Strength of evidence based on a grading system.

Grade Criteria
Substantiated include a clear role of FAIR data in relation to agricultural performance include a comprehensive methodological approach that demonstrates FAIR data implementation processes scientific, evidence based, empirical, quantitative and/or case study Partially substantiated include a clear role of FAIR data in relation to agricultural performance include a comprehensive methodological approach that demonstrates FAIR data implementation processes scientific, evidence based, empirical, quantitative and/or case study Unsubstantiated studies discussing the role of FAIR data in other contexts and do not qualify for the eligibility criteria Finally, eight studies met the final appraisal criteria. The eight finalists were examined and assessed for their strength of evidence. Of the final eight studies, two (N = 2 or 25%) were graded as partially substantiated with the strength of evidence II, and six (N = 6 or 75%) were graded as substantiated with the strength of evidence I ( Table 2). Average citation rate of the included studies is calculated as 7. In this literature review, the included studies were shortlisted based on the inclusion criteria that were confined to the studies: (1) classified under the six Web of Science categories: Agriculture Multidisciplinary, Agriculture Dairy Animal Science, Soil Science, Plant Sciences, Green Sustainable Science Technology and Computer Science Interdisciplinary Applications; (2) listed as article and/or review; (3) written in the English language; (4) comprise applied implications of FAIR data, its implementation and comprehensive methodological approach; (5) published with the top-ranked publishers, i.e., Elsevier, Springer Nature, MDPI, Wiley and Taylor & Francis, in all the journals nominated for the research area; and (6) published within last six (2016-present) years. There were three studies selected through Google Scholar, using the snowballing search technique, based on the reference lists of the studies obtained from Web of Science search. Notably, during our literature review process, we found three studies, i.e., Capalbo et al. [15], Weersink et al. [11] and Wolfert et al. [44], describing the importance of data/big data in the agricultural performance without relating to FAIR data principles. Our search also found four research papers, i.e., Koers et al. [45], Robinson et al. [46], Roitsch et al. [47], Ingram et al. [48] and Bahlo et al. [49], recommending the adoption of FAIR data principles to enhance agricultural performance, without explaining how or why. These papers do not meet the selections criteria; hence, they were excluded during screening and eligibility processes.
It is acknowledged that farming is a multifaceted business with no 'best bet' or 'one method fits all' solution due to the multiplicity of unforeseen factors. All the above criteria may introduce bias in this systematic review that may influence or contrast with the findings.

Presentation/Interpretation
According to the Web of Science research areas, two studies were categorised under 'Plant Sciences', one listed under 'Remote Sensing', and five studies relates to Agriculture, Science and Technology, Genetics & Heredity, Environmental Science, Ecology, and Geology categories Moreover, the included eight studies have been published to different prominent journals (Table 3). Although the trend is increasing (Figure 2), the minimal number of studies demonstrates very slow adoption of FAIR data principles reported in agricultural research publications, which may reflect on the slow uptake by the agricultural researchers and practitioners. Geology categories Moreover, the included eight studies have been published to different prominent journals (Table 3). Although the trend is increasing (Figure 2), the minimal number of studies demonstrates very slow adoption of FAIR data principles reported in agricultural research publications, which may reflect on the slow uptake by the agricultural researchers and practitioners.

Findings
Since the publication of the FAIR data guidelines [22], there are only eight published studies found through this systematic literature review approach of their adoption in agricultural data. Though these studies confirm the significant role that FAIR data can have on agricultural operational and business performance, the actual implementation of FAIR data principles in the agricultural industry appears to be minimal. Figure 3 demonstrates indicators, sub-indicators of FAIR data, their impacts on sustainable agriculture performance and their assimilation with the sustainability framework [49][50][51]. The detailed analysis of the final selected papers with respect to their objectives, roles towards agricultural performance, scope and the sources or tools employed, is listed in Table 4.

Findings
Since the publication of the FAIR data guidelines [23], there are only eight published studies found through this systematic literature review approach of their adoption in agricultural data. Though these studies confirm the significant role that FAIR data can have on agricultural operational and business performance, the actual implementation of FAIR data principles in the agricultural industry appears to be minimal. Figure 3 demonstrates indicators, sub-indicators of FAIR data, their impacts on sustainable agriculture performance and their assimilation with the sustainability framework [50,51]. The detailed analysis of the final selected papers with respect to their objectives, roles towards agricultural performance, scope and the sources or tools employed, is listed in Table 4.   Rural Household Multiple Indicator Survey (RHoMIS) aims to:  promptly characterise a sequence of key indicators across the range of agricultural products and off farm activities, together with marketplace integration, nutrition, food security, poverty and greenhouse gas (GHG) emissions.  measure on-and off-farm paths to food security, various diets and variations in poverty for rural smallholder farm households.  attain sustainable development goals that require more improved sustainable food production and development of rural economies.  better understand the relationships between farming practices, livelihood and the influences on farm performance and household welfare that help with developing targeted investment to advance in agronomic development. Trustworthy indicators at farm-household level of both agri. performance and household wellbeing help to better understand and model these relationships, and to review, revise and update the strategy and execution of intermediations involved officials through an extensive array of changing geographies and socio-economic features.  ‚ promptly characterise a sequence of key indicators across the range of agricultural products and off farm activities, together with marketplace integration, nutrition, food security, poverty and greenhouse gas (GHG) emissions. ‚ measure on-and off-farm paths to food security, various diets and variations in poverty for rural smallholder farm households. ‚ attain sustainable development goals that require more improved sustainable food production and development of rural economies. ‚ better understand the relationships between farming practices, livelihood and the influences on farm performance and household welfare that help with developing targeted investment to advance in agronomic development. Trustworthy indicators at farm-household level of both agri. performance and household wellbeing help to better understand and model these relationships, and to review, revise and update the strategy and execution of intermediations involved officials through an extensive array of changing geographies and socio-economic features. ‚ manage propagation of survey tools and indicators heading to illogical, incoherent and un-interoperable datasets.

2.
Harrison et al. [37] Objective: To develop high-quality and rich-supporting metadata (in line with FAIR data guidelines) to describe the project's animals, specimens, cell cultures and experimental assays. Functional annotation of animal genomes (FAANG) metadata helps in: ‚ creating sample and experiment metadata standards to enhance data recording. ‚ standardising global vocabularies and or expressions by using ontologies. ‚ utilising the wide-ranging livestock datasets produced outside of the project by employing less rigorous legacy guidelines. ‚ developing authentication software to help the community in fulfilling the metadata standards and to input their data to the public archives, hence actively support the community. ‚ providing a community data portal that classifies all sample and experimental datasets by using a single-focused user interface. ‚ successfully dealing with the challenges faced by the consumers in creating infrastructure that mutually and efficiently coordinate genome-to-phenotype research activities. ‚ maximising the usefulness and inter-comparison of assay data. ‚ creating a powerful genome-to-phenotype resource and supports on-going developments in animal data standards as a whole, to support the community.

Dorich et al. [38]
Objective: To create the Global N 2 O Database (following FAIR data principles) to serve as a repository for N 2 O datasets to be publicly available data and for analytical advances. ‚ improve Nitrous oxide (N 2 O) emission estimates that are primarily obtained from agriculture and is an intoxicating greenhouse gas (GHG) that is roughly 300 times more intense than CO 2 and is the most hazardous ozone-draining material. ‚ improve N 2 O assessments, detection of hotspots and alleviation priority zones, and better interpretation of climate change feedbacks. ‚ help with providing an opportunity for methods comparisons by collecting exact data from all practices. ‚ provide value-added computation of annual emissions within a monitoring, reporting and verification process (MRV) scheme for enhanced policy making, for instance greenhouse gas exchanges and to reduce N 2 O emissions. ‚ help to moderate and better prepare for climate change by developing and verifying practical abatement strategies in the land use sector, as agriculture has a cause and effect' correlation with the climate change. increases the visibility and findability of researchers' investigation, as the data can be assigned a digital object identifier (DOI), which is essential for data publications and data citations. ‚ allows targeted dataset queries and to better the discovery and reusability of research data.

6.
Arnaud et al. [41] Objective: To annotate multidisciplinary research data with the appropriate ontologies to stimulate the ontology content to fill the gap rather than developing completely new ontologies. Annotation of and integrative, multifaceted, versatile, associative research data with the most suitable ontologies aims to comply with the FAIR data principles, and to strengthen the findability of data for further reuse, hence adding to the return on investment (RoI) for information collection and storage. It further aims to: ‚ provide most appropriate ontologies with more applicable and reliable data control, including data stewardship, ownership and robust policy. ‚ enhance technological structure (essential softwares, connectivity and servers) that plays key role in arranging and classifying the tangible data structures, i.e., ontologies, taxonomies and structured vocabularies to finally form a supportable data management system. ‚ exclusively increase the influence of agronomic research and development (R&D) by following FAIR data guidelines to build community trust level.

7.
Hackett et al. [42] Objective: To present biodiversity data workflow, i.e., data collection and curation, from multiple sources while abiding by FAIR data principles, to enable researchers, managers, and policymakers to address issues of global and future concern. Scope: -Biodiversity associated with globally vulnerable prairie fen wetlands. Plant diversity research and species-focused studies concerning the biology, ecology and behaviour of the federally endangered Poweshiek skipperling. Global biodiversity information facility (GBIF) data sets: ‚ help to deal with the heterogeneity of biodiversity data issues, faced by data collections units, research and management communities, by implementing FAIR data principles for large-scale research. ‚ provides new opportunities to better understand vibrant natural systems and help establishing more applied data resource management. ‚ successfully address specific queries in the fields of phylogenomics, biogeography climatology, ecology and evolution, etc.

8.
Singh et al. [43] Objective: To develop a single database for annotated plant stress images that supports FAIR principles (of accessibility and reusability) to propose an overarching strategy for utilizing ML techniques that methodically enables the application of plant stress phenotyping at multiple scales across different types of stresses, program goals, and environments. Plant stress evaluations measure the visible signs and/or indications of stress and its progress on different plant units (e.g., leaf, stem, or roots) at the leaf, canopy, plot and field levels. A comprehensive database for annotated plant stress images, embedded with FAIR data principles, aims to: ‚ choose stress-resistant varieties and to develop better stress-management schemes. ‚ standardise visual evaluations and to utilise imaging techniques to better enhance the precision and trustworthiness of stress assessment in contrast with single-handed visual measurement. ‚ enhance machine learning (ML) approaches combined with image-based phenotyping to get up-to-date insights from highly organised, annotated (supported with explanations and/or comments), and high-dimensional (provided with the staggeringly higher number of dimensions) datasets across wide-ranging stresses and crops. ‚ concurrently build up the pace, precision, trustworthiness and scalability of stress phenotyping, and agility for highly varying program objectives; whereas innovative ML algorithms offer extended plant stress phenotyping techniques to deal with these challenges. ‚ advance mechanisation and accuracy of plant stress gravity evaluations that improve the proportion of genetic gain within crops, providing comprehensive management approaches. Notably, stress gravity evaluations in plants are important for appraising management strategies, plant breeding choice approaches and checking novel varieties for their capacity to alleviate crop damages. Additionally, efficiently quantify plant traits under different environmental circumstances with a stipulated precision and accuracy at various scales from organs to canopies.
Sustainable and enhanced agricultural production highly rely on the farming strategies, methods and decision making made by the stakeholders [5,6,53]. Accomplishment of FAIR data principles ensures data findability, accessibility, interoperability and reusability that extensively contributes better decision making towards both the operations and business management. Figure 3 demonstrates on how the sub-indicator/characteristics of FAIR data lead to sustainable agricultural performance indicators, and the way the sustainability indicators assimilate with the sustainable agricultural performance indicators, ultimately complementing the sustainability triple bottom line framework.

Discussion
The analysis of papers found through this systematic literature review clearly demonstrate that the provision of FAIR data can help improve agriculture operational and business performances. The multidimensional challenges in agriculture demand better decision making, which in turn relies on better access to data for wiser decision making. In this regard, a big responsibility lies on the shoulders of the stakeholders, i.e., farmers, farm managers, agronomists, service providers, researchers, etc. to make their data FAIR.
However, the systematic literature review also found only a few documented cases of practical examples that relate FAIR data to agricultural performance. While there may be many reasons for the low number of published case studies of adoption of FAIR data in agriculture, this review strongly indicates a need for social science research to explore what those reasons may be. Clearly, the stakeholders' value propositions for the adoption of FAIR data in agriculture need to be better understood.
In accordance with Rogers' [54], diffusion of innovation theory simply having knowledge of a new idea is not enough. By and large, informative individuals go through a persuasion stage to build either positive or negative attitudes towards the new idea, in accordance with innovation decision processes. Every novel idea carries a certain level of hesitation as the individual consumers of various personality types weigh up their appetite for risk and capacity for adopting change and so on. It is keenly realised that researchers should incorporate and comprehend the farmers' social perspectives, seeing that the comprehension of attitude and social capacity are the key indicators towards viable agriculture and central to better explore the community attitudes and behaviour [55,56].
Firstly, agriculture practitioners' attitude towards data and data sources in addition to their capability to employ the information are critical factors for the useful utilisation of those data [57,58]. Data are key in decision making [27], whereas the practitioners' attitude towards data authenticity, data source, its genuineness and applicability are critical factors towards its usefulness [57,58]. Secondly, practitioners and stakeholders play their respective roles towards the betterment of agriculture. If agricultural data-as a key input in decision-making-are not findable, and accessible, they will be of no use even though they are well researched. Stakeholders' data comprehension and knowledge exchange at all levels are important factors towards agricultural improvement [59]. If the data are not comprehendible to the end-users, they will not be used in accordance with the notion of the behavioural economics [60]. Thirdly, the available agriculture data are found disparate, disorganised and disarrayed [61]. The required datasets are either not available [62,63] or the consumers are provided with restricted and/or limited access [19].
Theory of reasoned action (TRA) uncovers that an individual's objective and decision making depends upon the level of information or data they have [64]. Stakeholders' knowledge building, including that of FAIR data, is essential. In this way, those with limited or no technical knowledge are asked to educate themselves with the emerging technology to better adapt with the modern advancements. Adoption of digital agriculture in general, and the adoption of FAIR data principles in particular, are facing several challenges. Politically, in Australia for instance, digital agriculture needs more proactive steps towards policy making, cooperation, administration and cross industry collaboration. Socially, digital literacy among all the key stakeholders can play a vital role to better comprehend value proposition of digital agriculture, and to bridge the trust gap between consumers, technology providers and data custodians. While device connectivity and the required data input are key prerequisites to make the technology work, the lack of mobile connectivity and internet telecommunications infrastructure, and limited or no access to the required data, curtail practitioners to use the technology at its best [65]. Economically, the Australian agriculture sector estimates an increase by 42% in its technology-oriented capital by 2030, whereas the farming sector needs to adopt the latest farming technologies and techniques to meet future production demands. Digital agriculture can add a gross value of AUD 20.3 billion [63], while better agricultural planning and appropriate farming techniques have a potential to further supplement AUD 100 billion to the Australian economy by 2030 [66].
The provision of FAIR data is a well-documented constraint in modern agriculture [19,67,68], but there is little to no research on why FAIR data are not made available. If FAIR data are widely regarded as important, why is it not widely adopted? Is stakeholders' knowledge and perception towards FAIR data a barrier? To comprehend these questions, a FAIR data process flowchart has been devised as a guiding template to direct the social research. Using plain language, this flowchart attempts to step an agricultural practitioner through the requirements for FAIR data to ascertain where they perceive barriers and difficulties in adopting FAIR data processes.
The flowchart (Figure 4) intends to test the extents to which each of the required FAIR data components (findability, accessibility, interoperability, reusability) present barriers to adoption, whether these barriers are equally distributed across the four components and whether there are specific steps within each component that present higher barriers than others. By troubleshooting the specific barriers of each requirement, the value propositions of adopting FAIR data in agriculture can be better understood and addressed. and techniques to meet future production demands. Digital agriculture can add a gross value of AUD 20.3 billion [63,66], while better agricultural planning and appropriate farming techniques have a potential to further supplement AUD 100 billion to the Australian economy by 2030 [67]. The provision of FAIR data is a well-documented constraint in modern agriculture [18,68,69], but there is little to no research on why FAIR data are not made available. If FAIR data are widely regarded as important, why is it not widely adopted? Is stakeholders' knowledge and perception towards FAIR data a barrier? To comprehend these questions, a FAIR data process flowchart has been devised as a guiding template to direct the social research. Using plain language, this flowchart attempts to step an agricultural practitioner through the requirements for FAIR data to ascertain where they perceive barriers and difficulties in adopting FAIR data processes.
The flowchart (Figure 4) intends to test the extents to which each of the required FAIR data components (findability, accessibility, interoperability, reusability) present barriers to adoption, whether these barriers are equally distributed across the four components and whether there are specific steps within each component that present higher barriers than others. By troubleshooting the specific barriers of each requirement, the value propositions of adopting FAIR data in agriculture can be better understood and addressed.

Conclusions
The advent of digital agriculture has provided agricultural practitioners with access to a plethora of internet resources, sensors and applications for decision support in their operations and businesses. The FAIR data principles were designed to address the challenge of how to harness the increasing volume of disparate, but relevant data to improve decision making and enhance agricultural performance. This systematic literature review reinforces this hypothesis but finds very few published examples of how adopting the principles are related to agricultural performance, indicating that the value proposition is yet to be realised. To explore this tardiness will require social science research to find the specific barriers in making data findable, accessible, interoperable and reusable, so that benefits of digital agricultural can be more broadly gained.

Conclusions
The advent of digital agriculture has provided agricultural practitioners with access to a plethora of internet resources, sensors and applications for decision support in their operations and businesses. The FAIR data principles were designed to address the challenge of how to harness the increasing volume of disparate, but relevant data to improve decision making and enhance agricultural performance. This systematic literature review reinforces this hypothesis but finds very few published examples of how adopting the principles are related to agricultural performance, indicating that the value proposition is yet to be realised. To explore this tardiness will require social science research to find the specific barriers in making data findable, accessible, interoperable and reusable, so that benefits of digital agricultural can be more broadly gained.